Floor for blast room with uniform down-draft ventilation



May 19, 1970 D. L. TEMPLE ET L 3,5

FLOOR FOR BLAST ROOM WITH UNIFORM DOWN-DRAFT VENTILATION Original Filed April 28, 1967 5 Sheets-Sheet 1 NATHAN 085 .ORNEYS 5 Sheets-Sheet 2 May 19, 1970 D. TEMPLE ET AL FLOOR FOR BLAST ROOM WITH UNIFORM DOWNDRAFT VENTILATION Original Filed April 28, 1967 May 19, 1970 D. L. TEMPLE ET AL 3,512,469

FLOOR FOR BLAST ROOM WITH UNIFORM DOWN-DRAFT VENTILATION Original Filed April 28, 1967 5 Sheets-Sheet 5 lNVENTO/ES DONALD L. TEMPLE FIG. 6 NATHAN cams W/ZW,

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May 19, 1970 FLOOR FOR BLAST ROOM WITH UNIFORM DOWN-DRAFT VENTILATION 5 SheetsSheet 5 Original Filed April 28, 1967 United States Patent 3,512,469 FLOOR FOR BLAST ROOM WITH UNIFORM DOWN-DRAFT VENTILATION Donald L. Temple and Nathan Oberg, Washington, Mo.,

assignors to Zero Manufacturing Company, Washington, Mo., a corporation of Missouri Original application Apr. 28, 1967, Ser. No. 634,586, now Patent No. 3,417,719. Divided and this application May 1, 1968, Ser. No. 725,869

Int. Cl. F241? 13/18 US. Cl. 98--31 6 Claims ABSTRACT OF THE DISCLOSURE A blast room which has air drawn through a pervious top downwardly through a perforated floor and means for separating and exhausting the air and collecting the blasting material. The top is louvered by three tiers of angle beams resting on supports and alternately disposed so that an upwardly directed air blast sufiicient to lift a beam moves same to block the space between tWo adjacent beams in the tier above. The floor includes a perforated grating lying on detached and readily removable beams of M cross section having apertures in the central lower apex, there being two inclined longitudinally extending plates within the beam on either side of said apex. In one embodiment the plates extend normally from the vertical legs of the beam. In another they are vertical. In a further embodiment an inclined angle beam is inverted above the apex of the M-beam with slots disposed along the edges of the angle beam..

CROSS REFERENCE TO RELATED APPLICATION This invention relates to a floor for a blast room with uniform down-draft ventilation and is a divisional app1i cation of my application Ser. No. 634,586, filed Apr. 28, 1967.

BACKGROUND OF THE INVENTION This invention relates to an enclosed blast room for a fine particle blast system. More particularly, it relates to an improved blast room of modular unit construction having a one-way type louvered roof and floor components which are readily removable for cleaning or other purposes.

Fine particle blasting has enjoyed wide acceptance in the last several years, especially since the advent of dry glass bead peening and reclaim systems which effectively separate the blasting particles from dust and debris arising from the blasting operation. The glass bead particles range in size between .005.026 inch diameter with diameters of .0035.0059 inch being popular for most applications. In recent years room-sized glass bead blasting chambers have made their appearance. Examples of such rooms are disclosed in Pats. Nos. 2,912,918 and 3,026,789 issued Nov. 17, 1959, and Mar. 27, 1962, to W. H. Mead. Prior to this, rooms for abrasive blast systems such as disclosed in Pat. No. 2,292,665 of Aug. 11, 1942, to C. B. Schneible, were Well-known and contemporary glass bead blast rooms have been adaptations of these systems. However, the abrasive blast systems largely utilized sand, shot or grit blasting materials which were relatively large and usually expendable. Glass beads and alumina oxides, however, present major packing and conveying problems in such a system. With known systems there is a tendency for overloading the sump and clogging, particularly in the floor area and when moisture is present. When such occurs, the lack of accessibility for cleaning is a major problem.

In addition, current roof structures either give insufficient protection against misdirected air blasts penetrat- 3 ,5 12,46 9 Patented May 1 9, 1 970 SUMMARY OF THE INVENTION The invention is directed to the structural units of the roof and floor which, in the case of the roof, is unique in that it is sufficiently opened to provide an improved air flow in comparison with current roofs for similar installations and will automatically close in response to a misdirected air stream somewhat in the same fashion as louvers, thereby preventing dust from escaping into the surrounding atmosphere. Since the individual beams of the roof are not welded or otherwise fastened to the supporting structure, the roof can be installed with less expense and also more easily cleaned or dismantled or both.

The floor construction includes characteristics which provide a clog-resistant duct for the evacuation of air, blasting material and debris unless undue moisture is introduced. In such event, the floor beams which are not welded or otherwise fastened to the foundation plate or to each other can easily be lifted and cleaned. As with the roof, the floor can be quickly installed. The compact and inherently strong trusslike construction of the floor beams permits a reduction in floor height and eliminates the requirement for much of the supporting structure which might otherwise be necessary.

BRIEF DESCRIPTION OF THE DRAWINGS The primary object of the invention is to provide the above advantages by the structure as disclosed and claimed. However, other objects, adaptabilities and capabilities will be appreciated by those skilled in the art to which the subject matter of the invention pertains, reference being had to the accompanying drawing, in which:

FIG. 1 is a schematic perspective view of a blast room in accordance with the invention;

FIG. 2 is a cross-sectional view of the blast room;

FIG. 3 is a cross-sectional view of a roof segment of the blast room;

FIG. 4 is a fragmentary exploded perspective view showing two roof angle beams supporting means;

FIG. 5 is a fragmentary perspective view of the floor design of the blast room;

FIG. 6 is a front sectional view of a floor beam shown in FIG. 5;

FIG. 7 is a side sectional view of a floor beam shown in FIG. 5;

FIG. 8 is a fragmentary perspective view of a further embodiment of the floor design of the blast room;

FIG. 9 is a front sectional view of a beam shown in FIG. 8 with the apertures 74 omitted;

FIG. 10 is a fragmentary perspective view of a still further embodiment of the floor design of the blast room; and

FIG. 11 is a front sectional view of a beam shown in FIG. 10.

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a blast room with conventional components comprising a separator and reclaim system -21 and a dry filter 22. The separator and reclaim system 21 is connected to the exhaust from the pick-up snout 77 of blast room 20 by an exhaust conduit 24. The separator and reclaim system 21, the dry filter 22, and the exhaust conduit 24, all being conventional and known in the field to which the invention pertains, do not require a detailed description for an understanding and use of the invention by a person skilled in the art.

back wall 27, and a front consisting of doors and 31.

These elements are also conventional and need not be described in detail for an understanding by a person skilled in the art.

The roof of the blast room 20 is designated generally 32, and the floor is designated generally 34.

From FIG. 1 it will be noted that the roof 32 comprises some eight modules 35. FIG. 3 shows a cross section of a typical module 35 which includes a framework 36. Supported within the module 35 by the framework 36 are three tiers of angle beams designated 37. These angle beams 37 lie on tent-shaped supports 43 (see FIG. 4) which are spot welded or otherwise fastened to the framework 36. Corresponding supports 43 are situated at both ends of the framework 36 so that each a ngle beam 37 spans a pair of the supports 43 located at the end of the framework 36. The angle beams 37 are composed of a thin gage metal (their thickness being exaggerated in the drawings) and are not secured to the supports 43 in the sense that they can be lifted freely from such supports. FIG. 4 illustrates an end of an angle beam 37 on support 43, and a further support 43 without its angle beam in a lower tier. If a blast is inadvertently directed upwardly to impinge upon one of the angle beams 37 of tier 40, such angle beam is raised thereby into the space between the adjacent angle beams 37 directly above in tier 41. In the same manner a blast hitting an angle beam in tier 41 moves it into the corresponding spaces between the adjacent angle beams 37 next above in tier 42. As a result, substantially no portion of the blast is permitted to escape through the roof 32. A grating 44 is laid across the upper portion of the beams 37 of tier 42, as shown in FIG. 3, which prevents the upward displacement of tier 42.

If desired, a loosely packed fibrous material mat 45 may be included within the framework 36 of each module 35 above the grate 44. Spanish moss is a satisfactory fibrous material for this purpose.

Protected lights 47 are secured to roof beams 50 which also function to receive and support the modules 35. As necessary and desired, utility inlets such as inlet 51 for blasting material and inlet 52 for fresh air supply to the operator are provided in the blast room 20.

In a blast room designed in accordance with the invention, air is drawn vertically downward through the roof 32 into the floor 34 at a rate of about fifty-five feet per minute. This compares with a rate of about forty feet per minute in known practical designs. One reason that a relatively high air flow rate can be achieved without unduly raising the static pressure on the blast room 20 lies in the design of the roof 32 as set forth above. However, of equal importance to the efficient and effective operation of the blast room 20 is a floor structure whereby the air laden with spent blasting material and other debris is continuously removed from the blast room 20 during blasting operations.

FIGS. 5, 6 and 7 show a preferred floor design embodiment. In this embodiment, floor beams 54, having an M- shaped cross section, are laid side by side across the foundation plate 57. The upper V of the M-shaped beams forms a hopper and at the lower apex of such hopper there are a plurality of slots 55 of sufficient size to permit the continuous exhaustion from the blast room of air, blasting material and the debris resulting from the blasting operation. It has been found that slots or ,4 by /2" disposed longitudinally with respect to floor beams 54 and spaced a quarter of an inch apart are satisfactory. Angle irons 56 span adjacent pairs of the floor beams 54 and provide immediate support for floor gratings 62 which may have braces 64 affixed thereto. If desired, an angle iron 56 may be left exposedQas illustrated in FIG. 5, whereby it also functions as a track to receive a wheeled work-supporting means such as dolly 65 as shown in FIG. 2. The dolly 65 is shown in FIG. 2 supporting a work piece 66 being subjected to blasting treatment. Secured on either side of the slots 55 within the lower portion of the floor beam 54 are right and left air divider plates 60 and 61. These are securely fastened within the beam by welding or other appropriate means and are inclined relative to the longitudinal length of the beam so that, as seen in FIGS. 2 and 7, there is substantially more space between the foundation plate 57 and the air divider plates 60 and 61 on the left-hand portion of the floor beams, where air discharges into pick-up snout 77, than on the right-hand portion. It is preferable that the inclination be sufficient so that the velocity of the air moving horizontally to the left, as seen in FIG. 2, under the air divider plates 60 and 61 is substantially uniform and similarly, air is drawn into the slots 55 at a substantially uniform velocity irrespective of their specific location in the blast room 20. It is preferred that the floor beam be bevelled inwardly on the right end side, as seen in profile in FIGS. '2 and 7.

The angle irons 56 are not secured to the floor beams 54 which in turn are not secured to the foundation plate 57. Thus to remove the floor beams 54 or any particular floor beam, all that is necessary is to lift and remove the associated floor grating 62, pick up and lay aside the angle irons 56, and lift out the floor beams 54, as desired.

It will be noted that the floor of this embodiment is a rib type floor supported by what is essentially a trusslike structure in the floor beams. The floor is compact in that it takes up little room, and floor assemblies can be added or deleted as required by the size of the particular blast room, or as otherwise may be desired for cleaning purposes.

FIGS. 8 and 9 show modified floor design. The same reference numerals have been used for parts similar to those previously described. In this embodiment, the floor beam 67 also has an M-shaped cross section. However, the central lower apex of the beam 67 is on the same level as the lower edges of the outer legs. A floor beam housing 70 receives the floor beam 67 and, if desired, may be secured thereto whereby a strong truss-like structure is formed. Within the V-portion of the floor beam 67 is received an inclined angle beam 71. The conveying duct 72 thus formed increases in size in the direction of the movement of air therein. Air is drawn uniformly int; the duct 72 through a plurality of slot-like passages 74 of sufficient size for that purpose. As in the prior embodiment, the various components are laid one upon the other so that the floor grating 62 is readily removable from the underlying supporting structure, the inclined angle beam 71 can be lifted from position for cleaning and, if desired, the floor beams -67, either with or separately from the floor beam housings '70, Can be lifted and removed from the foundation plate 57.

A still further embodiment of the floor design is shown in FIGS. 10 and 11. Again the same reference numerals have been used for similar parts previously shown and described. The foundation plate 57 supports floor beam housings 70 in a side-to-side relationship, each of which receives floor beams 54 of M-shaped cross section. The central lower apex of the beam 54 has a plurality of slots 55. Beam braces 75 may be secured to the floor beams 54 or to the gratings 62. In this particular embodiment, however, it is preferred that they be secured to the beams 54. Space is provided between selected beam braces 75 for the receipt of angle irons 56 which function as rails for dolly 65 or the like. A tapered air duct which is U-shaped in cross section lies under the slots 55. It increases in size in the direction of air carried therethrough to equalize the air velocity through the slots 55 and to provide the necessary space for conveying the blasting media to the pickup snout 77 of the blast room 20 and eventually to the reclaim system. As with the previous floor embodiments, the individual components can be removed merely by lifting same so as to provide ready accessibility for cleaning or other purposes.

Although we have described preferred embodiments of our invention, it is to be understood that it is capable of other adaptations and modifications within the scope of the appended claims.

Having thus described our invention, what we claim as new and desire to secure by Letters Patent of the United States is:

1. A floor (34) for a blast room which comprises:

a substantially flat horizontal foundation surface (57).

a plurality of adjacent trough members (54, 67) supported by said foundation surface,

said trough members and further contacting members (60, 61, 71, 76) defining longitudinal channels (72) above said foundation surface and along the sides of said trough members,

spaced openings (55, 74) in said trough members leading to said channels,

means (21) for causing air from said blast room to move into said channels through said openings and thence through said channels, said channels having an increasing capacity in the direction of said air flow whereby air is drawn into each of said openings at a substantially uniform velocity, and

a horizontal grating (62) disposed above said trough members.

2. A floor (34) for a blast room (20) which comprises:

a substantially flat horizontal foundation surface (57),

a plurality of adjacent trough members (54) supported by said foundation surface, the sides of said trough members and said foundation surface defining longitudinal channels therebetween,

spaced openings (55) in said trough members lead'mg to said channels,

means (21) for causing air from said blast room to move into said channels through said openings and thence through said channels,

said channels having an increasing capacity in the direction of said air flow whereby air is drawn into each of said openings at a substantially uniform velocity, and

a horizontal grating (62) disposed above said trough members.

3. A floor for a blast room which comprises:

a foundation plate (57),

a plurality of similar beams of M-shaped cross section (54) each disposed on said foundation plate in sideby-side relationship,

a plurality of apertures through each of said M-beams along the central apex thereof,

each of said M-beams including a pair of plates (60-, 61) secured within said M-beam with one on each side of the central apex thereof, each of said plates being inclined relative to the length of its corresponding M-beam, and

a grating (62) disposed over said M-beams, said grating being perforated and having attached downwardly extending braces (64) interlocking with said M-beams.

4. Structure in accordance with claim 3 including angle beams (56) spanning and interlocking adjacent M-beams, said grating carried by said angle beams.

5. Structure in accordance with claim 3 wherein said gratings are free from connections to said M-beams and liftably removable therefrom.

6. Structure in accordance with claim 3 wherein each of said M-bearns are free from connections to adjoining M-beams and said foundation plate and are liftably removable therefrom.

References Cited UNITED STATES PATENTS 2,912,918 11/1959 Mead 98-33 X WILLIAM E. WAYNER, Primary Examiner US. Cl. X.R. 98-42 

